Discovery of N-[(1 S, 2 S)-3-(4-Chlorophenyl)-2-(3-cyanophenyl)-1

Kimberly Rosko,. ∞. Alison Strack,. ∞. Donald J. Marsh,§. Yue Feng,§ Sanjeev Kumar,‡ Koppara Samuel,‡ Wenji Yin,‡. Lex H. T. Van der Ploeg...
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Letters Discovery of N-[(1S,2S)-3-(4-Chlorophenyl)-2(3-cyanophenyl)-1-methylpropyl]-2-methyl-2{[5-(trifluoromethyl)pyridin-2-yl]oxy}propanamide (MK-0364), a Novel, Acyclic Cannabinoid-1 Receptor Inverse Agonist for the Treatment of Obesity Figure 1. Structures of SR141716 and SLV319.

Linus S. Lin,*,† Thomas J. Lanza, Jr.,† James P. Jewell,† Ping Liu,† Shrenik K. Shah,† Hongbo Qi,† Xinchun Tong,† Junying Wang,† Suoyu S. Xu,† Tung M. Fong,§ Chun-Pyn Shen,§ Julie Lao,§ Jing Chen Xiao,§ Lauren P. Shearman,∞ D. Sloan Stribling,∞ Kimberly Rosko,∞ Alison Strack,∞ Donald J. Marsh,§ Yue Feng,§ Sanjeev Kumar,‡ Koppara Samuel,‡ Wenji Yin,‡ Lex H. T. Van der Ploeg,§,# Mark T. Goulet,†,# and William K. Hagmann† Departments of Medicinal Chemistry, Metabolic Disorders, Pharmacology, and Drug Metabolism, Merck Research Laboratories, Rahway, New Jersey 07065 ReceiVed August 17, 2006 Abstract: The discovery of novel acyclic amide cannabinoid-1 receptor inverse agonists is described. They are potent, selective, orally bioavailable, and active in rodent models of food intake and body weight reduction. A major focus of the optimization process was to increase in vivo efficacy and to reduce the potential for formation of reactive metabolites. These efforts led to the identification of compound 48 for development as a clinical candidate for the treatment of obesity.

Obesity is a serious and chronic medical condition that is rapidly growing throughout the world. In many cases, the excessive body weight is the root cause of subsequent comorbidities, including diabetes, hypertension, cardiovascular disease, cancer, and arthritis.1 Although lifestyle modifications may be the preferred approach for the management of obesity, it is often insufficient or unsustainable. Therefore, new anti-obesity therapeutics are actively pursued. The involvement of the cannabinoid receptor system in regulating feeding behavior has been demonstrated in animal and clinical studies.2,3 Several cannabinoid-1 receptor (CB1R) inverse agonists including SR141716 (rimonabant)4 and SLV3195 (Figure 1) have been reported to be efficacious in various models of feeding behavior, and rimonabant has been approved in the EU for the treatment of obesity. Herein, the discovery of novel, acyclic CB1R inverse agonists is described. Our efforts started with a screening lead (1) that was determined to be a racemic mixture of the anti-diastereomers6 (Figure 2). Preparative chiral HPLC separation afforded the (S,S)-isomer 2 and the (R,R)-isomer 3. The stereochemical assignments were established by X-ray analysis. The racemate of the syn-diastereomers of 1 was synthesized and was less * To whom correspondence should be addressed. Phone: 732-594-8391. Fax: 732-594-5966. E-mail: [email protected]. † Department of Medicinal Chemistry. § Department of Metabolic Disorders. ∞ Department of Pharmacology. ‡ Department of Drug Metabolism. # Current affiliation: MRL Boston.

Figure 2. Racemic 1 was separated into slower eluting (S,S)enantiomer 2 and faster eluting (R,R)-enantiomer 3.

active (CB1R IC50 ) 95 ( 23 nM). The more potent enantiomer 3 demonstrated good pharmacokinetic properties in the rat (1 mg/kg iv, 2 mg/kg po, F ) 68%, t1/2 ) 2 h). However, when evaluated in the diet-induced obese (DIO) rat model, 3 (up to 10 mg/kg po) showed no significant effects on overnight food intake or body weight reduction, thereby setting the stage for lead optimization. After a thorough investigation of the backbone scaffold of 1 that did not yield any significant improvements in potency, further efforts focused on varying the substituents of the two aromatic rings of the amine fragment. The synthetic route began with substituted phenyl acetates 4 (Scheme 1). Base-catalyzed alkylation with benzyl halides was followed by conversion to the Weinreb amide 6. Reaction of 6 with methyl Grignard reagent afforded ketone 7. Reduction of 7 was accomplished with sodium borohydride or lithium tri(sec-butyl)borohydride to afford 8 as the major diastereomer.7 The reduction with sodium borohydride was generally less diastereoselective (4:1) than with tri(sec-butyl)borohydride (>10:1). The resulting secondary alcohol 8 was converted to the amine 9, which was subsequently coupled to a fibric acid to give the anti-diastereomer 10 as the major product in racemic form. The less selective borohydride reduction provided a useful amount of the minor syn-diastereomers of 10 for structure-activity-relationship (SAR) comparisons. The individual enantiomers of 10d were prepared by an enantiospecific route (Scheme 2), starting from (1R,2R)- or (1S,2S)-1-phenylpropylene oxide (11 or 12).7 Epoxide opening with 4-chlorobenzylmagnesium chloride afforded the secondary alcohols (S,R)-13 and (R,S)-14, respectively, which were separately converted to the amines (S,S)-15 and (R,R)-16 and subsequently to the amides 17 and 18. With the enantiomerically pure amines 15 and 16 in hand, the SAR of the aromatic ring of the acid moiety was then addressed. The synthesis of the acid fragments followed several different routes (Scheme 3). The first route was a one-step reaction between 1,1,1-trichloro-tert-butanol 19 and a substituted phenol 20 to afford fibrate 21.8 Since hydroxypyridines were generally poor substrates for this reaction, an alternative route was developed. Reaction of 2- or 3-hydroxypyridine (23, 24) with benzyl lactate 22 under Mitsunobu conditions afforded

10.1021/jm060996+ CCC: $33.50 © 2006 American Chemical Society Published on Web 12/21/2006

Letters

Scheme 1a

Journal of Medicinal Chemistry, 2006, Vol. 49, No. 26 7585

Scheme 4a

a (a) Y-PhCH Br, KHMDS, -78 °C f room temp; (b) MeONH(Me)‚HCl, 2 Me2AlCl, room temp; (c) MeMgCl, ether, 0 °C; (d) NaBH4, MeOH or LiBH(sec-Bu)3, THF, -78 °C; (e) MsCl, Et3N; (f) NaN3, DMF, 100 °C; (g) H2, Boc2O, PtO2 (cat.), EtOAc; (i) HC/dioxane, EtOAc; (j) fibric acid, (COCl)2, then N-methylmorpholine, CH2Cl2.

Scheme 2a

a (a) 4-ClPhCH MgCl, 0 °C; (b) Scheme 1, steps e-i; (c) fibric acid, 2 (COCl)2, then N-methylmorpholine, CH2Cl2.

Scheme 3a

a (a) NaOH, acetone; (b) DEAD, Ph P, CH Cl ; (c) KHMDS, MeI, THF, 3 2 2 -78 °C; (d) H2, Pd/C (cat.), MeOH; (e) SEMCl; (f) BnO2CCH(Me)OTf, 60 °C.

esters 25 and 26 along with some N-alkylated side products. Methylation of 25 and 26 followed by hydrogenolysis afforded acids 29 and 30. Because 4-hydroxypyridine (31) afforded the N-alkylated product exclusively under Mitsunobu conditions,

a (a) Cs CO , CH CN, 50 °C; (b) NaOH, H O/MeOH; (c) PyBop, 2 3 3 2 N-methylmorpholine, CH2Cl2, room temp; (d) Scheme 1, steps e-g; (e) Zn(CN)2, Pd2(dba)3, dppf, DMF/H2O (98:2), 100 °C; (f) HCl/dioxane, EtOAc.

another procedure was investigated. Protection of the pyridine nitrogen with a SEM group provided 32, which was reacted with benzyl lactate O-triflate to yield the desired O-alkylation product. The SEM group was cleaved upon workup to give 33, which was converted to acid 34 under standard conditions. These new acids were then coupled to amine 15 to give the desired amides (35a-h). Further optimization resulted in a two-step synthesis of pyridine acids 41 and 42 (Scheme 4). Reaction of appropriately substituted 2-hydroxypyridines with R-bromoisobutyrate in the presence of cesium carbonate afforded the esters 39 and 40, which were hydrolyzed to acids 41 and 42. Coupling of these acids with the (S,S)-amine 15 provided amides 43 and 44. The bromo-substituted amine 46 was converted to the cyano amine 47 under palladium-catalyzed cyanation conditions.9 Amide coupling with acid 42 followed by HPLC on a chiral column afforded the more potent (S,S)-isomer 48.10 Inhibition data of [3H]CP-55940 binding to recombinant human CB1R and CB2R expressed in CHO cells are summarized in Table 1. The anti-diastereomers were generally 2to 10-fold more potent than the syn-diastereomers, so only the data for the anti-diastereomers are listed. Deletion of the 4-chloro substituent from phenyl ring A in 10d resulted in an increase in binding affinity, whereas replacement with fluorine resulted in a loss of potency (10a). Fluorine substitution at the 2-position had little effect (10c), but substitution at the 3-position enhanced potency (10b). For phenyl ring B, the 4-substituent was required for optimal potency (10d,f,g vs 10h). Substitution at the 2-position resulted in significant loss of binding activity (10e). It is interesting that whereas the more potent enantiomer of 1 is 3 with the (2R,3R)-configuration, the more potent enantiomer of 10d is 17 with the (2S,3S)-configuration. Employing the potency enhancing substitution pattern on the amine fragment found in 10d (17), the SAR of the aryloxy group was then explored (Table 2). Both 4- and 3-substitutions on the phenyl ring of the acid moiety were tolerated and were preferred over 2-substitution. The 3,5-difluoro analogue 35e is among the more potent compounds. In addition, replacement of the phenyl ring with a 2-pyridyl group was well tolerated (35f), although the regioisomeric 3- or 4-pyridyl groups were less favorable (35g and 35h). Compound 35e was also found

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Table 1. Inhibition of CB1R and CB2R (IC50, nM)a by Substituted Amidesb

b

compd

X

Y

CB1R IC50, nM

CB2R IC50, nM

1 (S,S)-2 (R,R)-3 10a 10b 10c 10d 10e 10f 10g 10h (S,S)-17 (R,R)-18 SR141716 SLV319

4-Cl 4-Cl 4-Cl 4-F 3-F 2-F H H H H H H H

4-Cl 4-Cl 4-Cl 4-Cl 4-Cl 4-Cl 4-Cl 2-Cl 4-CF3 4-F H 4-Cl 4-Cl

20 ( 12 48 ( 17 13 ( 6 90 ( 4 2.8 ( 0.8 12 ( 3 2.5 ( 1.1 140 ( 25 3.4 ( 1.4 14 ( 0.6 33 ( 0.3 3.0 ( 1.2 170 ( 110 6.1 ( 2.5 17 ( 8

1100 ( 1100 >2000 600 ( 200 530 ( 6 410 ( 130 610 ( 370

770 ( 620 1700 ( 700 600 ( 650 1100 ( 200

a Inhibition of binding (mean ( SD) (n g 2 independent experiments).11 Racemic mixture of the anti-diastereomers except as noted.

Table 2. Inhibition of CB1R and CB2R (IC50, nM)a by Substituted Amidesb

b

compd

X

Ar

CB1R IC50, nM

CB2R IC50, nM

17a 35a 35b 35c 35d 35e 35f 35g 35h 43 44 48

H H H H H H H H H H H CN

4-Cl-Ph 3-Cl-Ph 2-Cl-Phc Ph 3-F-Ph 3,5-F2-Ph 2-pyr 3-pyrc 4-pyrc 5-Cl-2-pyr 5-CF3-2-pyr 5-CF3-2-pyr

3.0 ( 1.2 1.5 ( 0.5 18 ( 4 2.0 ( 1.4 1.6 ( 0.8 1.1 ( 1.0 1.8 ( 1.4 19 ( 3 17 ( 1 1.3 ( 0.3 0.5 ( 0.2 0.3 ( 0.1

770 ( 620 190 ( 80 450 ( 180 290 ( 60 200 ( 110 88 ( 28 1200 ( 300 100 ( 20 140 ( 20 290 ( 60

a Inhibition of binding (mean ( SD) (n g 2 independent experiments).11 (S,S)-Enantiomer. c Racemic mixture of anti-diastereomers.

to have good pharmacokinetic properties (1 mg/kg iv, 2 mg/kg po, F ) 19%, t1/2 ) 2.4 h) and brain exposure (1 mg/kg iv, brain and plasma concentrations of 0.27 and 0.35 µM at 1 h, respectively) in the rat. In contrast to 3, 35e was highly efficacious in the DIO rat model, resulting in dose-dependent reduction in overnight food intake (-55 ( 2% and -81 ( 6% at 3 and 10 mg/kg po, respectively; P < 0.05 vs vehicle at both doses). Formation of reactive metabolites and subsequent covalent modifications of proteins are implicated in cases of allergic and/ or idiosyncratic immune-mediated toxicities.12 Because such toxicities may not manifest themselves until the later stages of development or after marketing, bioactivation should be minimized in drug candidates. Compound 35e was evaluated for the potential of reactive metabolite formation. Tritiated 35e was incubated with human and rat liver microsomes and afforded very high levels of irreversible binding of radioactivity (1700 pmol equiv./mg protein).13 When the incubation was performed with glutathione as an additive, covalent adducts of 35e with glutathione were detected by LC-MS. Careful analysis of the

Letters Table 3. Covalent Binding to Human Liver Microsomal Proteins Obtained by Incubation of Tritiated Compounds13

a

compd

bindinga

35c 35e 35f 43 44 48 (MK-0364)

3900 ( 300 1700 ( 320 910 ( 110 300 ( 81 88 ( 4 27 ( 2

pmol equiv/mg protein at 1 h of incubation.

MS pattern suggested that the covalent linkage was formed between the 3,5-difluorophenoxy fragment of 35e and the sulfhydryl group of glutathione. Presumably, the electron-rich phenyl ring was oxidized to a putative arene oxide intermediate that then reacted with glutathione or nucleophilic species on microsomal proteins, resulting in formation of covalent adducts. The mechanism of bioactivation for 35e was believed to be oxidation of the electron rich aryloxy group, so a more electrondeficient aryl group would be expected to be less prone to such metabolic activation. Indeed, 35f was found to have reduced levels of covalent binding (910 pmol equiv/mg protein) when the 3,5-difluorophenyl ring was replaced with the more electrondeficient 2-pyridyl ring (Table 3).13 Further reduction of bioactivation was accomplished by introduction of an electronwithdrawing substituent such as a 5-chlorine (3-fold) or 5-trifluoromethyl group (10-fold). The addition of the 5-trifluoromethyl group (44) also improved potency and selectivity relative to the unsubstituted pyridine derivative 35f. The residual covalent binding in 44 (88 pmol equiv/mg protein) was thought to result from the bioactivation of the unsubstituted phenyl ring A. Substitution of ring A with an electron-withdrawing group was sought to further reduce the potential for bioactivation. This effort was highlighted by the incorporation of a cyano substituent, which afforded a CB1R inverse agonist (48, MK-0364) with minimal potential for covalent protein binding. Compound 48 was an exceptionally potent and selective (900fold over CB2) CB1R inverse agonist with >500-fold improvement in affinity over the original lead (1). In a functional assay of cyclic-AMP production, 48 was determined to be an inverse agonist (EC50 ) 2.4 ( 1.4 nM, -123% maximal activation; relative to CP-55940). Compound 48 also had a good pharmacokinetic profile in three species (rat, 1 mg/kg iv, 2 mg/kg po, F ) 74%, t1/2 ) 2.7 h; dog, 0.2 mg/kg iv, 0.4 mg/kg po, F ) 31%; t1/2 ) 14 h; rhesus monkey, 0.2 mg/kg iv, 0.4 mg/kg po, F ) 31%, t1/2 ) 3.6 h) and good brain exposure (1 mg/kg iv, brain and plasma concentrations of 0.11 and 0.18 µM at 1 h, respectively). The in vivo activity of 48 was first assessed with a rat hypothermia model. In this model, a rapid 4-5 °C decrease in body temperature was first induced by CB1R agonist CP-55940. Administration of 48 (3 mg/kg iv) completely blocked the temperature decrease (P < 0.00001 vs vehicle), consistent with total in vivo inhibition of the CB1 receptors.14 The effects of 48 on feeding behavior were evaluated in the DIO rat model. After 14 days of treatment at 0.3, 1, and 3 mg/kg (po, qd), a sustained and dose-dependent reduction relative to the vehicletreated animals in body weight (4 ( 1%, 5 ( 1%, and 7 ( 1%, respectively; P < 0.05) was observed.14 The effects on food intake and body weight were shown to be mediated by CB1R by the lack of such effects in Cnr1 knockout mice.14 More details of the in vivo pharmacology of 48 will be reported in future publications.14 In summary, we have discovered a series of novel, acyclic CB1R inverse agonists that are potent, selective, and orally

Letters

Journal of Medicinal Chemistry, 2006, Vol. 49, No. 26 7587

bioavailable. A major focus of the optimization effort was to increase in vivo efficacy and to attenuate the potential for bioactivation of the initial lead. These compounds are active in models of feeding behavior and hypothermia, and 48 (MK-0364) is currently undergoing clinical evaluation for the treatment of obesity. Acknowledgment. We acknowledge the contributions of Ms. Nancy Tsou, Dr. Richard Ball, Dr. David Mathre, Ms. Dorothy Levorse, Dr. Karen Owens, and many members of the Laboratory of Animal Resources.

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Supporting Information Available: Experimental details and elemental analysis results. This material is available free of charge via the Internet at http://pubs.acs.org.

References (1) Olshansky, S. J.; Passaro, D. J.; Hershow, R. C.; Layden, J.; Carnes, B. A.; Brody, J.; Hayflick, L.; Butler, R. N.; Allison, D. B.; Ludwig, D. S. A potential decline in life expectancy in the United States in the 21st century. New Engl. J. Med. 2005, 352, 1138-1145. (2) Pertwee, R. G. Cannabinoid receptor ligands: clinical and neuropharmalogical considerations relevant to future drug discovery and development. Expert Opin. InVest. Drugs 2000, 9, 1553-1571. (3) (a) Smith, R. A.; Fathi, Z. Recent advances in the research and development of CB1 antagonists. IDrugs 2005, 8, 53-66. (b) Lange, J. H. M.; Kruse, C. G. Medicinal chemistry strategies to CB1 cannabinoid receptor antagonists. Drug DiscoVery Today 2005, 10, 693-702. (4) (a) Sorbera, L. A.; Castaner, J.; Silvestre, J. S. Rimonabant hydrochloride. Drugs Future 2005, 30, 128-137. (b) Van Gaal, L. F. Rissanen, A. M.; Scheen, A. J.; Ziegler, O.; Rossner, S. Effects of the cannabinoid-1 receptor blocker rimonabant on weight reduction and cardiovascular risk factors in overweight patients: 1-year experience from the RIO-Europe study. Lancet 2005, 365, 13891397. (5) Lange, J. H. M.; Coolen, H. K. A. C.; van Stuivenberg, H. H.; Dijksman, J. A. R.; Herremans, A. H. J.; Ronken, E.; Keizer, H. G.; Tipker, K.; McCreary, A. C.; Veerman, W.; Wals, H. C.; Stork, B.; Verveer, P. C.; den Hartog, A. P.; de Jong, N. M. J.; Adolfs, T. J. P.; Hoogendoorn, J.; Kruse, C. G. Synthesis, biological properties, and molecular modeling investigations of novel 3,4-diarylpyrazolines as potent and selective CB1 cannabinoid receptor antagonists. J. Med. Chem. 2004, 47, 627-643. Recent reports of other selective CB1 inverse agonists: (a) Muccioli, G. G.; Wouters, J.; Charlier, C.; Scriba, G. K. E.; Pizza, T.; Pace, P. D.; Martino, P. D.; Poppitz, W.; Poupaert, J. H.; Lambert, D. M. Synthesis and activity of 1,3,5triphenylimidazolidine-2,4-diones and 1,3,5-triphenyl-2-thioxoimidazolin-4-ones: characterization of new CB1 cannabinoid receptor inverse agonists/antagonists. J. Med. Chem. 2006, 49, 872-882; (b) Carpino, P. A.; Griffith, D. A.; Sakya, S.; Dow, R. L.; Black, S. C.; Hadcock, J. R.; Iredale, P. A.; Scott, D. O.; Fichtner, M. W.; Rose, C. R.; Day, R.; Dibrino, J.; Butler, M.; DeBartolo, D. B.; Dutcher, D.; Gautreau, D.; Lizanao, J. S.; O’Connor, R. E.; Sands, M. A.; Kelly-Sullivan, D.; Ward, K. M. New bicyclic cannabinoid receptor-1 (CB1-R) antagonists. Bioorg. Med. Chem. Lett. 2006, 16, 731-736. (c) Debenham, J. S.; Madsen-Duggan, C. B.; Walsh, T. F.; Wang, J.; Tong, X.; Doss, G. A.; Lao, J.; Fong, T. M.; Schaeffer, M.-T.; Xiao, J. C.; Huang, C. R,-R. C.; Shen, C.-P.; Feng, Y.; March, D. J.; Stribling, D. S.; Shearman, L. P.; Strack, A. M.; MacIntyre, D. E.; Van der Ploeg, L. H. T.; Goulet, M. T. Synthesis of functionalized

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1,8-naphthyidinones and their evaluation as novel, orally active CB1 receptor inverse agonists. Bioorg. Med. Chem. Lett. 2006, 16, 681685. (d) Plummer, C. W.; Finke, P. E.; Mills, S. G.; Wang, J.; Tong, X.; Doss, G. A.; Fong, T. M.; Lao, J. Z.; Schaeffer, M.-T.; Chen, J.; Shen, C.-P.; Stribling, D. S.; Shearman, L. P.; Strack, A. M.; Van der Ploeg, L. H. T. Synthesis and activity of 4,5-diarylimidazoles as human CB1 receptor inverse agonists. Bioorg. Med. Chem. Lett. 2005, 15, 1441-1446. The synthesis and stereochemical assignment of this amine have been reported: (a) Schultz, E. M.; Bolhofer, W. A.; Augenblick, A.; Bicking, J. B.; Habecker, C. N.; Horner, J. K.; Kwong, S. F.; Pietruszkiewcz, A. M. Maleamic acids that affect plasma cholesterol and penicillin excretion. J. Med. Chem. 1967, 10, 717-724. (b) Pines, H. S.; Chemerda, J. M.; Kozlowski, M. A.; Weinstock, L. M.; Davis, P.; Handelsman, B.; Grenda, V. J.; Lindberg, G. W. The stereochemistry of 2,3-diphenyl-1-methylpropylamine. J. Med. Chem. 1967, 10, 725-728. Iwasawa, Y.; Shibata, J.; Nonoshita, K.; Arai, S.; Masaki, H.; Tomimoto, K. Stereoselective synthesis of J-104,118 and J-104,123, novel, potent inhibitors of squalene synthase. Tetrahedron 1996, 52, 13881-13894. Corey, E. J.; Barcza, S.; Klotmann, G. Directed conversion of the phenoxy grouping into a variety of cyclic polyfunctional systems. J. Am. Chem. Soc. 1969, 91, 4782-4786. Maligres, P. E.; Waters, M. S.; Fleitz, F.; Askin, D. A highly catalytic robust palladium catalyzed cyanation of aryl bromides. Tetrahedron Lett. 1999, 40, 8193-8195. The stereochemistry of 36 was confirmed by X-ray analysis. Also see: Burns, D. H.; Chen, A. M.; Gibson, R. E.; Goulet, M. T.; Hagmann, W. K.; Hamill, T. G.; Jewell, J. P.; Lin, L. S.; Liu, P.; Peresypkin, A. V. Radiolabeled cannabinoid-1 receptor modulators. PCT Patent Application WO2005/009479A1, 2005. (a) Shen, C.-P.; Xiao, J. C.; Armstrong, H.; Hagmann, W.; Fong, T. M. F200A substitution in the third transmembrane helix of human cannabinoid CB1 receptor converts AM2233 from receptor agonist to inverse agonist. Eur. J. Pharmacol. 2006, 531, 41-46. (b) Felder, C. C.; Joyce, K. E.; Briley, E. M.; Mansouri, J.; Mackie, K.; Blond, O.; Lai, Y.; Ma, A. L.; Mitchell, R. L. Comparison of the pharmacology and signal transduction of the human cannabinoid CB1 and CB2 receptors. Mol. Pharmacol. 1995, 48, 443-450. (a) Evans, D. C.; Watt, A. P.; Nicoll-Griffith, D. A.; Baillie, T. A. Drug-protein adducts: an industry perspective on minimizing the potential for drug bioactivation in drug discovery and development. Chem. Res. Toxicol. 2004, 17, 3-16. (b) Nassar, A. F.; Lopez, A. A. Strategies for dealing with reactive intermediates in drug discovery and development. Curr. Opin. Drug DiscoVery DeV. 2004, 7, 126136. Samuel, K.; Yin, W.; Stearns, R. A.; Tang, Y. S.; Chaudhary, A. G.; Jewell, J. P.; Lanza, T., Jr.; Lin, L. S.; Hagmann, W. K.; Evans, D. C.; Kumar, S. Addressing the metabolic activation potential of new leads in drug discovery: a case study using ion trap mass spectrometry and tritium labeling techniques. J. Mass Spectrom. 2003, 38, 211-221. Fong, T. M.; Guan, X.-M.; Marsh, D. J.; Shen, C.-P.; Stribling, D. S.; Rosko, K. M.; Lao, J.; Yu, H.; Feng, Y.; Xiao, J. C.; Van der Ploeg, L. H. T.; Goulet, M. T.; Hagmann, W. K.; Lin, L. S.; Lanza, T. J., Jr.; Jewell, J. P.; Liu, P.; Shah, S. K.; Qi, H.; Tong, X.; Wang, J.; Xu, S. S.; Francis, B.; Strack, A. M.; MacIntyre, D. E.; Shearman, L. P. Anti-obesity efficacy of a novel cannabinoid-1 receptor inverse agonist MK-0364 in rodents. J. Pharmacol. Exp. Ther., submitted for publication.

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